小麦幼胚培养再生单性雌花的研究

通过45个基因型的小麦（Triticum aestivumL.)幼胚培养,发现有11.1%的基因型从靠近再生芽基部的愈伤组织上分化形成花器官,再生花芽呈裸露的,多子房丛生的,具有藏盛羽毛状柱头而缺乏雄蕊,外稃,内稃和颖片的单性雄花。组织切片观察发现,其雌蕊起源于再生芽附近的分生组织细胞,并通过次生雌蕊再生的方式形成从生状,其羽毛状结构的发育先于子房中胚珠的分化,除正常的单胚珠外,还发现双生胚珠分化。X^2独立性检验结果显示,花芽再生率存在强烈的基因型效应,小麦品种YA-1表现突出（44.4%)。其花芽再生潜力能在不同年份间较好地再现,说明YA-1的花芽再生能力具有相对稳定性,与脱分化培养基的效应相比,YA-1的花芽再生效率主要受继代培养基成分的影响,其中,6-BA,NAA和加倍无机铁盐的配比较2,4,-D和正常浓度无机铁盐的配比更有利于YA-1的幼胚培养再生花芽,同时,外植体实验表明,YA-1的幼穗和成熟胚培养无任何成花反应,而其幼胚外植体具有特异的花芽再生能力。据此认为,YA-1的幼胚培养有助于为小麦花发育机理研究建立理想的实验系统。     

丽格海棠的离体快繁

取丽格海棠幼叶为外植体,在诱导培养基MS＋BA 0．5mg/L NAA 1.0mm/L上培养20d左右,开始分化花芽,培养40d丛生芽长满整个外植体,丛生芽的增殖培养以MS＋BA 0．5mg/L为佳,芽长得大且粗壮,粗壮芽转入无激素的1／2MS生根培养基,生根率达100％。     

小麦幼胚培养高效成株系统的建立

研究探讨了不同的基因型、幼胚取材时期、4℃处理时间、盾片接种方式、分化及生根条件等对小麦幼胚培养再生成株特性的影响,并在此基础上建立了一套高效、可靠、重复性好的小麦组培再生系统。优化条件下,该系统从幼胚诱导致密愈伤组织的频率为89％,致密愈伤组织的分化频率诱导2周时为95％,培养近3个月时仍可达50％以上。此外还发现部分叶状结构当转至新鲜的分化培养基上时能够进一步发育成为芽苗。分化的芽苗在生根培养基上大多生成丛生苗。从基部切开后,每棵芽苗／分蘖均可独立成株。组培苗均可正常地开花结实。     

不同激素对花生离体分化的影响

对TDZ和2,4-D等激素在花生成熟胚外植体分化中的影响进行了研究.结果表明,花生成熟胚3～5 d龄实生苗的幼叶和胚轴在低浓度TDZ的诱导下,可分化产生高频不定芽和少量体细胞胚,转到无激素MS培养基或MS BA 0.5 mg/L NAA 0.4 mg/L的培养基后形成丛生苗.丛生苗分离后转入含1/2 MS(大量元素) IBA 0.4 mg/L的培养基中诱导生根,可形成完整的再生植株.幼叶分化率高于胚轴,但胚轴分化成苗速度快.无菌水浸泡16～24 h的胚轴在5～ 30 mg/L 2,4-D的诱导下,分化产生低频不定芽;而胚叶则产生高频体细胞胚,但畸形较严重.     

提高小麦愈伤组织分化频率的因素

研究了影响小麦愈伤组织诱导、芽分化及其植株再生的一些因素。结果表明：在愈伤组织诱导和继代过程中添加ＡＢＡ（１ ．０ｍｇ／Ｌ） 有利于小麦中晚期幼胚致密愈伤组织的诱导及再生能力的保持;外植体来源尤其是基因型对长期培养的愈伤组织再生能力有很大影响; 不同的外源激素（ ＫＴ、６ＢＡ、ＩＡＡ、ＴＤＺ和玉米素等） 也影响芽分化频率,其中ＴＤＺ可明显提高芽分化频率;在转入分化培养前对愈伤组织进行干燥处理可有效地提高其芽分化频率;在生根培养基中添加适量的ＩＡＡ 或ＮＡＡ 可有效促进生根。     

不同基因型玉米愈伤组织诱导与植株再生研究

以5个玉米品系幼胚为外植体,研究了基因型、2,4-D浓度以及胚龄对愈伤组织诱导的影响;6-BA对愈伤组织分化的影响;以及IBA对再生芽生根的影响。结果表明：除。31外,其他基因型的外植体在相同条件下均可诱导出愈伤组织,但是不同基因型间存在显著差异;2,4-D浓度和胚龄显著影响愈伤组织的诱导,且2,4-D浓度为2．0mg／L,胚龄在11—13d之间时,玉米愈伤组织诱导率较高且质量较好。将愈伤组织转入分化培养基后,6-BA促进了愈伤组织的再分化;在生根培养基中,IBA促进了再生芽生根,经过炼苗后移栽获得再生植株。     

花生叶片离体培养花器官分化及其开花结果研究

以花生幼叶为外植体进行离体培养,研究BA浓度对花器官分化的影响并进一步观察试管内花器官的发育.结果表明:经MSB 1mg/LBA 0.5mg/LKIN 2mg/LIAA培养基诱导的愈伤组织,转接到附加1～3mg/LBA的MSB培养基上培养,均能直接诱导分化花器官,但2mg/LBA的诱导效率最高达21.13%;诱导分化的花器官转接到MSB培养基继续培养,部分花器官可以在试管内开花、受精、成针、结实.试验实现了以花生幼叶为外植体,在试管内完成诱导花芽、开花、受精、形成果针、子房膨大,直至形成荚果等过程,为离体条件下研究花生花器官分化、荚果及种子发育提供了技术体系和材料.     

橡胶树未成苗体细胞胚的茎芽分化及利用

以橡胶树未成苗体细胞胚为试材,选取未成苗双子叶胚、连体胚、多子叶胚、单子叶胚和子叶愈伤化胚作为外植体,研究不同体细胞胚类型的外植体分化茎芽的情况,并利用其进行幼态微型芽条的培育研究。结果表明:在植株诱导培养基中培养80d后,未成苗双子叶胚、连体胚、多子叶胚、单子叶胚、子叶愈伤化胚均能分化出芽,双子叶胚分化率最高(达90%),单子叶胚最低(20%),多子叶胚和连体胚最多可分化出芽3个,双子叶胚2个。幼态微型芽条增殖的最优培养基为MS+6-BA2mg·L-1或MS+6-BA2mg·L-1+KT1mg·L-1,而添加NAA对芽的伸长有抑制作用;适宜幼态微型芽条伸长培养的基本培养基为MS。     

提高小麦愈伤组织分化频率的因素

研究了影响小麦愈伤组织诱导、芽分化及其植株再生的一些因素。结果表明：在愈伤组织诱导和继代过程中添加ＡＢＡ（１．０ｍｇ／Ｌ）有利于小麦中晚期幼胚致密愈伤组织的诱导及再生能力的保持;外植体来源尤其是基因型对长期培养的愈伤组织再生能力有很大影响;不同的外源激素（ＫＴ、６－ＢＡ、ＩＡＡ、ＴＤＺ和玉米素等）也影响芽分化频率,其中ＴＤＺ可明显提高芽分化频率;在转入分化培养前对愈伤组织进行干燥处理可有效地提高其     

基因枪转化小麦幼胚的再生培养与转基因植株的获得

以小麦幼胚为受体,用基因枪法对Trx-S反义基因 目的基因 和Bar基因 标记基因 进行了共转化,以轰击后的小麦幼胚为实验材料,对幼胚培养的基本培养基、分化和生根培养基进行了筛选优化.结果表明:4种基本培养基中,L3培养基的成愈率最高,且增殖速度快;MS培养基次之.以L3为基本培养基,分化培养基中添加NAA1mg·L-1和ZT2mg·L-1配比对愈伤组织诱导分化的效果最好,分化率达到50%以上.1/2MS培养基中添加IAA0.8mg·L-1的生根效果好,且移栽成活率高.以优化的培养方案对来自7个小麦品种的幼胚进行转化与再生培养,多数品种的出愈率都达到90%以上,分化率在40%以上,并在5个品种上获得再生植株,经检测证实在4个品种上获得转基因再生植株.     

小麦成熟胚高频植株再生系统的建立

在研究小麦成熟种子不同预处理时间、不同种类和浓度生长调节物质、分化培养基中是否添加CuSO4、不同外植体类型和不同放置方式对小麦成熟胚愈伤组织诱导和分化的基础上,建立了一套高效、可靠、重复性好的小麦成熟胚高频植株再生系统.以小麦成熟种子完整胚作为外植体的诱导频率为100%;除掉胚的原胚芽部位生长出的芽苗后,转分化的分化频率达到42.50%.     

普通小麦与鸭茅状摩擦禾的远缘杂交：Ⅱ.未成熟胚的培养

培养了由２６个小麦品种（系）用鸭茅状摩擦禾的花粉授粉１４天后获得６４５个未成熟的胚。结果表明,未成熟胚培养的植株再生频率与胚的小麦基因型的杂交亲和性无关,胚的发育程度直接影响胚培养的结果,离体时分化完全的未成熟胚在无激素的培养基上可以迅速萌发成工轩,而分化未完全的小胚在无激素的培养基上分化进程不能继续,而且在无激素补充的情况下,萌发过程一旦起动,即使将这些胚转至补加了激素的胚分化培养基上,分化过程     

Comparative analysis of the differential regeneration response of various genotypes of <Emphasis Type="Italic">Triticum aestivum</Emphasis>, <Emphasis Type="Italic">Triticum durum</Emphasis> and <Emphasis Type="Italic">Triticum dicoccum</Emphasis>

An efficient genotype independent, in vitro regeneration system was developed for nine popular Indian wheat cultivars, three each of Triticum aestivum L. viz., CPAN1676, HD2329 and PBW343, Triticum durum Desf. viz., PDW215, PDW233 and WH896, and Triticum dicoccum Schrank. Schubl. viz., DDK1001, DDK1025 and DDK1029, by manipulating the concentration and time of exposure to the growth regulator, thidiazuron (TDZ). A total of 18 (for immature inflorescence and embryo explant) and six (for mature embryo explant) different combinations of growth regulators were tried for callusing and regeneration, respectively. Media combination with low concentration of TDZ (2.2 μM) in combination to auxin and/or cytokinin (depending upon culture stage), was found to be effective for immature and mature explants. Compact, nodular and highly embryogenic calli were obtained by using immature embryo, immature inflorescence and mature embryo explants, and regeneration frequency up to 25 shoots/explant with an overall 80% regeneration was achieved. Comparable regeneration frequency was achieved for mature embryo explants. No separate hormone combination for rooting was required and plantlets ready to transfer to soil could be obtained in a short period of 8–10 weeks. This protocol can be used for raising transgenic plants for functional genomics analysis of agronomically important traits in the three species of wheat.     

小麦不同生理状态的幼穗和幼胚盾片与诱导分化能力关系的研究

用植物组织培养的方法,研究了冬小麦品种鄂恩1号和品系鄂55072不同生理状态的幼穗和幼胚盾片与诱导分化的关系。结果表明,长度在0.4-2.0cm间的幼穗和直径在0.4-1.5mm间的盾片随生理状态不同,其诱导和分化频率有明显的差异,幼嫩的材料再生频率较高。经SAS统计分析,发现0.5-1.0cm长的幼穗和直径为0.4-1.1mm的盾片是处于诱导分化的最佳生理时期的实验材料,平均每个胚性愈伤组织的植株再生分别达到3.17和5.63株。通过比较幼穗和幼胚盾片的植物组织培养结果,发现幼胚盾片比幼穗愈伤组织出现早,生长快,植株再生绿苗率高,这表明小麦幼胚盾片是较好的植物组织培养的材料。     

Comparative analysis of direct plant regeneration from immature leaf whorl and floral explants for three elite US sugarcane (Saccharum spp. hybrids) genotypes

Sugarcane (Saccharum spp. hybrids) is an important commodity field crop in tropical and subtropical countries providing sugar and biofuel feedstock and occupying a critical and strategic position in the global economy. This study was conducted to evaluate, compare, and optimize a rapid direct regeneration tissue culture system from immature leaf whorl and pre-emergent floral explants for three elite US sugarcane genotypes: CP84-1198, CP88-1762, and CP89-2143. Direct regeneration of adventitious shoot buds from the immature leaf roll explants and subsequent elongation and rooting of shoot buds was successfully obtained on modified Murashige and Skoog salt medium supplemented with 5 mg l^–1 α-naphthaleneacetic acid and 0.5 mg l^?1 kinetin. Significant genotype-specific differences in the morphogenetic potential of leaf roll explants were discernible with the explant developmental stage (explant position along the leaf roll axis) and orientation during in vitro culture. The highest number of shoots was regenerated from CP88-1762, followed by CP89-2143 and CP84-1198 from explants closest to the meristem that were oriented horizontally (CP88-1762) or vertically (CP89-2143 and CP84-1198) on the culture medium. Immature inflorescence-derived explants from all three genotypes when cultured on the above medium for 2 wk rapidly produced shoots, followed by rooting on medium supplemented with 4 mg l^?1 indole-3-butyric acid. The regeneration protocols yielded robust rooted plantlets from immature leaf roll explants within 4 to 6 wk, which were readily acclimatized under greenhouse conditions.     

Source, etiolation and orientation of explants affect in vitro regeneration of Venus fly-trap (Dionaea muscipula)

In vitro culture of Venus fly-trap (Dionaea muscipula) was initiated using flower stalk explants. Activated charcoal was required for bud initiation, but omitted in the subculture of regenerated plantlets. Regenerated plants were subsequently used as explant source for investigations concerning effects of source of tissue, etiolation, orientation and illumination of leaf explants on plant regeneration. Etiolation of source plantlets increased the rate of regeneration from explants and decreased explant failure. Generally, adventitious buds developed at the adaxial side and proximal end of an explant. However, when explants were incubated in the dark, 20–30% of bud initiation occurred at the distal end. The site of shoot regeneration on a leaf explant was affected by both illumination and orientation of explants. Placing an explant adaxial side up resulted in the highest rate of regeneration. The most effective condition for plantlet regeneration was found with etiolated petioles incubated with the adaxial side facing the light. Received: 18 March 1998 / Revision received: 12 August 1998 / Accepted: 7 September 1998     

Efficient callus induction and plant regeneration from mature embryo culture of winter wheat (Triticum aestivum L.) genotypes

Immature and mature embryos of 12 common winter wheat (Triticum aestivum) genotypes were cultured in vitro to develop an efficient method of callus formation and plant regeneration from mature embryo culture, and to compare the responses of both embryo cultures. Fifteen days after anthesis, immature embryos were aseptically dissected from seeds and placed with the scutellum upwards on a solid agar medium containing the inorganic components of Murashige and Skoog (MS) and 2 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D). Mature embryos were moved slightly in the imbibed seeds. The seeds with moved embryos were placed furrow downwards in dishes containing 8 mg/l 2,4-D for callus induction. The developed calli and regenerated plants were maintained on 2,4-D-free MS medium. Plants regenerated from both embryo cultures were vernalized and grown to maturity in soil. Regenerated plantlets all maintained the hexaploid chromosome number. A strong genotypic effect on the culture responses was found for both explant cultures. Callus induction rate, regeneration capacity of callus and number of plants regenerated were independent of each other. Mature embryos had a high frequency of callus induction and regeneration capacity, and therefore, being available throughout the year, can be used as an effective explant source in wheat tissue culture. Received: 4 February 1997 / Revision received: 1 April 1997 / Accepted: 5 May 1997     

温度和水分对不同基因型小麦未成熟胚体细胞胚胎发生以及分化能力的影响

对小麦未成熟胚盾片组织离体再生途径中,未成熟胚发育时期以及不同小麦品种的体细胞胚发生能力和体细胞胚的分化能力进行了研究,在所 试的14个小麦品种中,筛选出具有很强的体细胞胚发生能力和体细胞胚分化能力的4个品种,西农1376、盐2号、85＋1－3和宝丰7228。为进一步给小麦离体遗传操作打下基础,研究还对温度的影响进行了分析。通过低温手段解决了胚性愈伤组织随继代天数的延长体细胞胚分化能力快速降低的问题,同时研究还首次分析了干燥处理对小麦体细胞胚转换能力的影响,建立起一套高效的小麦离体培养再生体系,而且该体系从接种未成熟胚到再生植株移至土壤只需10－12周时间,避免了长期培养过程中存在的体细胞变异问题。     

赤霉素对大岩桐花蕾离体培养直接再生花芽的影响（简报）

植物经过一定时期的营养生长(或感受外界信号)后,就能产生成花刺激物。成花刺激物被运输到茎尖,诱导发生一系列的反应。随后其分生组织在一定时期内处于一个相对稳定的状态,即成花决定态。植物成花决定态建立的过程称为成花决定。对成花决定的研究进行了许多年,但是其确切的机理仍不清楚.     

赤霉素对大岩桐花蕾离体培养直接再生花芽的影响(简报)

植物经过一定时期的营养生长(或感受外界信号)后,就能产生成花刺激物。成花刺激物被运输到茎尖,诱导发生一系列的反应。随后其分生组织在一定时期内处于一个相对稳定的状态,即成花决定态。植物成花决定态建立的过程称为成花决定。对